This document summarizes research on copeptin, a peptide released along with arginine vasopressin (AVP). It discusses copeptin's stability and role as a marker for AVP levels. The document then examines research showing copeptin may serve as a diagnostic and prognostic marker for various diseases associated with diabetes, including diabetes insipidus, metabolic syndrome, diabetes mellitus, nonalcoholic steatohepatitis, and related complications. Studies found higher copeptin levels correlated with insulin resistance and risk of developing these conditions. The document concludes that copeptin measurement may be useful for differential diagnosis of diseases and as a potential marker for development of metabolic disorders and liver conditions.
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Copeptin: A Novel Marker for Diagnosis and Prognosis of Various Diseases Associated With Diabetes
1. BOHR International Journal of General and Internal Medicine
2022, Vol. 1, No. 1, pp. 45â49
https://doi.org/10.54646/bijgim.009
www.bohrpub.com
Copeptin: A Novel Marker for Diagnosis and Prognosis of Various
Diseases Associated With Diabetes
Randa Salah Gomaa
Medical Physiology Department, Faculty of Human Medicine, Zagazig University, Zagazig, Egypt
E-mail: rsgomaa@medicine.zu.edu.eg
Abstract. Copeptin is an arginine vasopressin (AVP) precursor whose C-terminal has evolved into 39 amino acids.
This AVP precursor is converted into equimolar amounts of copeptin, neurophysin II, and AVP. A strong connection
between the release of AVP and copeptin was observed. Measurement of AVP concentration remains complicated
since AVP is an unstable peptide and, additionally, it is bound by platelets. Copeptin remains stable in serum or
plasma for several days in a warm environment and testing for copeptin yields findings in 1 h. Consequently, the
quantity of copeptin might serve as a perfect replacement for reflecting the level of AVP.
Copeptin has become identified as a beneficial measure in various diseases. The physiology and structure of
copeptin, as well as its potential, to act as a predictive and diagnostic indicator of different diseases associated with
diabetes, are the goals of the current review.
Keywords: Arginine vasopressin, copeptin, diabetes insipidus, diabetes mellitus, metabolic syndrome.
INTRODUCTION
A group of metabolic illnesses known as diabetes includes
polyuria, polydipsia, and weight loss. Diabetes mellitus
[DM] is a metabolic disorder marked by impaired glu-
cose homeostasis that causes blood sugar to rise owing
to insufficient insulin production, insulin action defects,
or both [1]. Two etiopathogenetic types account for the
majority of diabetes cases. The first is type 1 diabetes,
which is brought on by a complete lack of insulin secretion.
The second is type 2 diabetes mellitus, which has both
insulin action resistance and inadequate compensatory
insulin production as its causes. Even before obvious
fasting hyperglycemia manifests in type 2 diabetes, patho-
logic and functional alterations in several tissues may
already be present in the early stages of aberrant glucose
metabolism [17].
Another type of diabetes is diabetes insipidus character-
ized by inadequate arginine vasopressin (AVP) synthesis
or efficacy, resulting in hypotonic polyuria that is accom-
panied by compensatory polydipsia. The role of AVP has
been reported among the causes of type 2 diabetes [15].
Copeptin and AVP are both descended from the same
progenitor molecule. Copeptin and AVP have a very sig-
nificant correlation; it reacts to osmotic, hemodynamic,
and general stressful stimuli just as quickly as AVP. The
physiological functions of homeostasis of fluid balance,
regulation of vascular tone, and control of endocrine stress
are roles of AVP, whereas the purpose of copeptin is yet
uncertain [4].
The 39-amino acid copeptin is created from the
C-terminal of the precursor arginine vasopressin (AVP).
AVP, neurophysin II, and copeptin are all produced in
equimolar levels from the AVP precursor. Additionally, a
strong connection between the release of AVP and copeptin
was observed [19]. Measurement of AVP concentration
remains complicated since AVP is an unstable peptide and,
additionally, it is bound by platelets. Compared with AVP,
copeptin is more stable because it remains stable in serum
or plasma for several days and has greater testability since
copeptin findings are accessible in 1 h [32] and at room
temperature [4] (Figure 1). Consequently, the quantity of
copeptin might serve as a perfect replacement to reflect the
level of AVP [7].
45
2. 46 Randa Salah Gomaa
Figure 1. Schematic presentation of the peptide precursor of argi-
nine vasopressin (AVP). The prohormone is packaged into neu-
rosecretory granules of magnocellular neurons. During axonal
transport of the granules from the hypothalamus to the posterior
pituitary, the final products are vasopressin, neurophysin II, and
copeptin. By enzymatic cleavage of the prohormone copeptin,
which is coreleased with AVP, is more stable following blood
withdrawal. Numbers denote the number of amino acids (aa)
present in each part [21].
The first section of this review will be devoted to the
structure, physiology, and role of copeptin. Second, the
main focus will be on how copeptin may be used as a
diagnostic and prognostic marker for various disorders
associated with diabetes.
PHYSIOLOGY OF COPEPTIN
Vasopressin is generated from the same precursor pep-
tide (pre-pro-vasopressin) as arginine copeptin and vaso-
pressin (AVP). Physiological factors induce both pep-
tide changes that are comparable to conditions, such as
osmotic stimulation, hypovolemia, or stress [23]. Condi-
tions, median Copeptin plasma levels in healthy volun-
teers at baseline were found to be 4.2 pmol/L, with a
wide range of 1â13.8 pmol/L and slightly higher values in
men than women. Copeptin levels do not vary with time
of day or with age. Consumption of meals and the men-
strual cycle do not appear to have any impact on copeptin
release [30].
Copeptin is rapidly removed from the circulation by
bioactive peptides rather than accumulating there, and
this fast clearance no longer takes place ex vivo. Copeptin
appears to be either broken down by tissue-bound pro-
teases or quickly excreted by the liver or kidneys. However,
no specific copeptin receptor or copeptin removal mecha-
nisms are currently understood [8].
While the precise physiological role of copeptin per se is
largely unclear, the physiological functions of AVP include
controlling vascular tone, fluid balance, and the endocrine
stress response [24]. However, it was asserted that the
chaperone-like molecule copeptin is crucial for the struc-
tural development of pro-AVP and may play a role in the
proper folding of the precursor molecule pre-pro-AVP by
acting on the glycosylation pattern [19].
Copeptinâs clinical significance as an AVP marker is
based on the fact that both AVP and copeptin are released
simultaneously after being transported from the hypotha-
lamus to the posterior pituitary.
According to data obtained from Google Scholar and the
PubMed database, the measurement of copeptin in sera
might serve as an important marker for assessing the risk
of complications as well as outcomes in several diseases
in general medicine, where vasopressinergic disturbances
may play a role in the pathogenesis [4].
COPEPTIN AS A MARKER FOR A DIABETES
INSIPIDUS DIFFERENTIAL DIAGNOSIS
Polyuria polydipsia syndrome is a term used to describe
several illnesses, and hypotonic polyuria is eventually
either a result of inadequate AVP production effectiveness
or is frequently accompanied by compensatory polydip-
sia. That syndrome falls into one of three categories:
First, because of inadequate AVP production in response
to osmotic stimulation, central diabetes insipidus (CDI)
develops. Second, renal insensitivity to typical AVP secre-
tion is the cause of nephrogenic diabetes insipidus (NDI).
Third, primary polydipsia persists despite intact AVP
secretion and a favorable renal response (PP) involving
excessive fluid intake per se that can produce polyuria [15].
The water deprivation test, which has since been
supplanted by the hypertonic saline test plus copeptin
measurement or arginine-stimulated copeptin measures,
was the commonly acknowledged test for decades as
a possible differential diagnosis for polyuria and poly-
dipsia. To differentiate between nephrogenic and cen-
tral diabetes insipidus, copeptin levels may be simply
assessed. Copeptin dependably differentiates several enti-
ties of polyuria polydipsia syndrome; baseline levels
>20 pmol/L without preceding fluid deprivation clas-
sify patients with nephrogenic diabetes insipidus, whereas
levels measured upon osmotic stimulation with hyper-
tonic saline or upon nonosmotic stimulation with argi-
nine differentiate primary polydipsia from central diabetes
insipidus [8]. (Figure 2 Copeptin as a marker in metabolic
disorders.)
Copeptin as a Marker in Metabolic Syndrome
Insulin resistance, central obesity, hypertension, hyper-
glycemia, and dyslipidemia are all metabolic disorders that
are considered to be part of the multifactorial condition
known as metabolic syndrome (MetS). MetS is highly
associated with the development of nonalcoholic fatty
3. Copeptin and Diabetes 47
Figure 2. A proposed new algorithm for differential diagnosis
polydipsia of polyuria syndrome [8].
liver disease, type 2 diabetes (T2DM), and cardiovascular
disease (CVD) [25].
Animal and human studies have shown that copeptin
acts as a valid surrogate measure for circulating levels
of AVP and that AVP has a function in lipid metabolism
and glucose homeostasis [2]. Several studies in humans
have shown that high copeptin levels were related to
T2DM [27], insulin resistance (IR), and other components
of MetS [13], mainly in the adult or elderly population [6].
Plasma copeptin is an independent predictor of metabolic
syndrome, including abdominal obesity, increased fasting
plasma glucose and insulin concentrations, the home-
ostasis model assessment of insulin resistance (HOMA-
IR), prevalent and incident type 2 diabetes (T2DM), and
decreased HDL-cholesterol [10].
Moreover, copeptin levels were shown to be greater in
patients with MetS compared to controls, and copeptin was
connected to MetS features such as BMI, waist, hyperten-
sion, lipids, and diabetes. These results show that elevated
copeptin levels in MetS may be used to track the course of
the disease, and copeptin readings may indicate the earliest
stage of MetS development [11].
In addition, the association of high copeptin levels with
MetS was described, and copeptin levels remained inde-
pendently associated with obesity, insulin resistance, and
chronic low-grade inflammation (Popovic et al., 2020).
Furthermore, there is a notable difference in plasma
copeptin levels between women and men. A significant
correlation was found between the degree of obesity
and copeptin but not the other parameters of the MetS.
Copeptin was significantly related to obesity in obese
children as pubertal boys but not prepubertal boys had
higher copeptin levels than girls [26]. On the contrary, it
was found that high-plasma copeptin was associated with
reduced insulin sensitivity and an increased risk for T2DM
in men [2].
Animal studies investigating the association between
serum copeptin level and metabolic syndrome (MetS)
parameters in both male and female albinos showed com-
parable results [16].
Copeptin as a Marker in Diabetes Mellitus
A multisystem metabolic condition called diabetes mellitus
(DM) is characterized by impaired glucose homeosta-
sis. The development of diabetes is affected by sev-
eral pathogenic processes. These range from autoimmune
destruction of the pancreatic cells and resulting insulin
deficiency to defects that result in resistance to insulin
action [1]. Two etiopathogenetic types account for the
majority of diabetes cases. The first is type 1 diabetes
mellitus, which is brought on by a complete lack of secreted
insulin. The second is type 2 diabetes mellitus; its cause
is a combination of resistance to insulin action and an
inadequate compensatory insulin secretory response [17].
The role of AVP has been found to have a part
in the pathogenesis of diabetes [9], and higher plasma
copeptin levels are linked to a higher risk of develop-
ing diabetes [31]. It was found that vasopressin levels
are increased in diabetics, and selective vasopressin V2-
receptor antagonist treatment abolished the albuminuria
elevation in diabetics [8].
Awad et al. [3] showed that there was a significant
elevation of plasma copeptin levels in adolescents with
T1DM, which is significantly higher in the presence of
microvascular complications, principally diabetic kidney
disease. Moreover, it was reported that there is a signifi-
cant increase in serum copeptin levels accompanied by a
positive correlation with the albumin/creatinine ratio in
children with T1DM [14].
Regarding insulin resistance, it was reported that serum
copeptin was significantly higher in comparison to con-
trols, with a substantial HOMA-IR connection among
obese kids and kids with insulin resistance [30].
Additionally, it was shown that there is a significant
association between serum copeptin levels and a posi-
tive family history of diabetes, indicating that copeptin
may have a role in predicting the onset of diabetes if
measured sooner. The same study discovered a positive
correlation of copeptin with urinary albumin excretion
(UAE), which is an early marker of renal damage, as well
as a urinary albumin-to-creatinine ratio (UACR), which is
the gold standard for diagnosing nephropathy, with the
copeptin not only in patients with DM but also levels at
various stages from the onset of diabetes to the onset of
its complications (controls, prediabetes, DM, and DM with
nephropathy) [22].
In a study that analyzed the plasma concentrations of
adropin, copeptin, neprilysin, and chitotriosidase in type 2
diabetic patients with or without retinopathy (DR), it was
found that copeptin is the best marker to assist in the
diagnosis of DR among others [20].
Copeptin as a Marker in Nonalcoholic Steatohepatitis
Barchetta et al. [5] showed a clear correlation between
high copeptin levels and the incidence of nonalcoholic fatty
4. 48 Randa Salah Gomaa
liver disease (NAFLD) and steatohepatitis (NASH). It was
found that copeptin levels predict the presence of biopsy-
proven NAFLD in obese individuals, regardless of body
adiposity and the existence of other metabolic disorders.
Elevated copeptin was hypothesized to be independently
linked to NAFLD in a population of mixed racial and
ethnic backgrounds [12].
Copeptin may be used to diagnose liver cirrhosis and
explain systemic infections that contribute to the progres-
sion of the condition [29]. Moreover, Kerbert et al. [18]
reported that higher copeptin concentrations upon hospital
admission are associated with acute-on-chronic liver fail-
ure (ACLF) in individuals hospitalized with acute decom-
pensation (AD) and those with classic AD of cirrhosis.
Copeptin has been independently linked to the short-term
survival and growth of ACLF. Copeptin is a sensitive
biomarker that can identify individuals with end-stage
liver disease who are at risk for short-term mortality
(7 days) as well [28].
CONCLUSION
Copeptin regularly reflects blood AVP concentrations and
is released at equimolar levels to AVP. Since copeptin is
stable ex vivo, is simple to test, and yields findings in an
hour, copeptin measurement offers a number of benefits
over AVP. Recently, copeptin has been suggested as a
potential marker for the differential diagnosis of polyuria-
polydipsia syndrome. Copeptin may be useful to serve as
a marker for the development of metabolic disorders such
as metabolic syndrome, diabetes, and liver conditions.
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